Method of determining a position using satellites

ABSTRACT

A method of determining the position of an observation point on the earth using M satellites on a stationary orbit which has a predetermined orbit inclination angle such that N (&lt;M) satelites are in the range of vision of the observation point. One of the N satellites generates a reference signal at a known time. This reference signal is sent directly to the observation point, sequentially relayed by the remaining satellites and transmitted from the respective satellites to the observation point. The observation point measures the differences in time of reception of the signals from the N satellites and determines the positions of the N satellites. The position of the observation point is determined as an intersecting point of the hyperboloids each placing the foci on adjacent two of the satellite positions.

BACKGROUND OF THE INVENTION

1. Field of the Invention

This invention relates to a method of determining the position of a signal reception point by receiving and processing radio wave signals transmitted from satellites in stationary orbits.

2. Prior Art

As conventional radio wave navigation systems, such as Decca, Omega and Loran-C which have oscillation sources on the earth are known. NNSS (Navy Navigation Satellite System) and GPS (Global Positioning System), both using satellites are also known. The systems using satellites allow the basis of position determination to be expanded to cosmic space so that enhanced accuracy in position measurement can be expected by the increased range of position detection and the provision of high-grade equipment. GPS of a type of measuring distance by time measurement has many superior performances in comparison with NNSS using the Doppler effect and is going to be a main system for navigation satellites in the future. The prior art will further be described with reference to such GPS in order to compare the present invention therewith.

FIG. 1 illustrates the disposition of GPS satellites. NAVSTAR (NAVigation System with Timing And Ranging) satellites 300, 301, 302 and 303 are at positions A', B', C' and D'. Each of the satellites has an accurate atomic clock to precisely maintain the accuracy of clock signals generated thereby. The atomic clock is calibrated by a signal sent from a control station on the earth so as to accurately tell the current time on the basis of the beginning of a week. The positions of NAVSTAR satellites are determined by measuring the time since the control station determines their orbits from the tracking data of the satellites. Thus, if an observer were at the position of a NAVSTAR satellite, the current time of the satellite and the orbit elements serve to determine the position of the observer. Then, the case where the observer observes the satellite at a position away therefrom is considered, the observation point being designated by P'. Assume that the observer has a clock with no calibrated high accuracy and with a fixed error from a reference time, and that the observer takes measurement at a time (Tn_(o) +Δt), where Tn_(o) is the exact time and Δt is an inherent error in the observer. Satellites 300, 301, 302, 303 are assumed to be measured by the observer at times Tn₁, Tn₂, Tn₃ and Tn₄, respectively. Taking into consideration the propagation time between the observer and the satellites, the following equations are obtained.

    A'P'=C(Tn.sub.o +Δt-Tn.sub.1)

    B'P'=C(Tn.sub.o +Δt-Tn.sub.2)

    C'P'=C(Tn.sub.o +Δt-Tn.sub.3)

    D'P'=C(Tn.sub.o +Δt-Tn.sub.4)

where, C is the velocity of light.

The above Equations have, as their unknown factors, Δt and three three-dimensional values defining the position P'. The Equations thus have solutions to enable the observer's position and time to be calibrated.

The NAVSTAR satellites are on six circular 12-hour orbits at the altitude of 20 degree, 183 km, the orbit inclination being at 55 degrees. Three satellites are positioned at an equal distance on each of such six orbits and totally 18 satellites are moving in the six orbits. The positions of the satellites are determined such that four of them are always visible from any point on the earth.

One control station and four monitoring stations are provided on the earth. Each station receives data and transmits necessary commands when the four satellites are in the visible range. Processing of the orbit data is performed by data processing equipment on the basis of the obtained data, and the time the calibration is practised on the basis of information from the primary reference.

GPS requires at least 18 NAVSTAR satellites to enable the position measuring at all points on the earth, and also requires highly accurate clocks and frequencies for generating original data for distance measurement. Thus they must be equipped with costly atomic clocks so that the control station can calibrate them once a week to maintain changes in time and frequencies within allowable ranges.

SUMMARY OF THE INVENTION

It is an object of the present invention to solve the above-mentioned problems and provide a method of determining the position an observation point, which is easier than and brings about the same advantages as conventional methods.

In order to attain this object, a method of determining the position of an observation point on the earth in accordance with the present invention can be determined by using M satellites disposed on a stationary orbit having a predetermined orbit inclination angle. The method comprises the steps of:

(a) transmitting a reference signal at a predetermined time from any one of N satellites (N<M) to the observation point and the subsequent satellite, the N satellites being simultaneously disposed in the range of vision of the observation point;

(b) causing the remaining (N-1) satellites to sequentially relay the reference signal received from the preceding satellite to the observation point and the subsequent satellite;

(c) measuring at the observation point the arrival times of the signals transmitted from the N satellites;

(d) calculating the position of each of the N satellites on the basis of the times obtained in the step (c) and estimated values of the orbit position of the stationary orbit provided by a control station on the earth; and

(e) determining at least three hyperboloids each placing the foci on adjacent two of the calculated positions of the N satellites, whereby the position of the observation point is determined at an intersecting point of the hyperboloids.

The above step (e) may include the step of calculating the mutual distance between adjacent two of the N satellites.

In an embodiment of the invention, five or more satellites are disposed on a stationary orbit having the orbit inclination angle of substantially 6 degrees; (a) a reference signal is transmitted at a predetermined time from any one of four satellites to the observation point and an adjacent one of the remaining three satellites, the four satellites being disposed to be simultaneously in the range of vision of the observation point such that the anomalies of the four satellites are separated from one another substantially at an angle of 120 degrees; (b) the reference signals are sequentially relayed by one of the remaining three satellites to the subsequent one; (c) the received reference signals are transmitted from the respective three satellites to the observation point; (d) the times of reception of the signals transmitted from the four satellites are determined at the observation point; (e) the positions of the four satellites are calculated by using the determined times and estimated values of the orbit position obtained from a control station on the earth; and (f) three hyperboloids each placing the foci on adjacent two of the calculated positions of the four satellites are determined, whereby the position of the observation point is determined as an intersecting point of the hyperboloids.

Any said one of the satellites can transmit the reference signal at a time calibrated by the control station. The calibrated time may be an integral-second time. Each of the satellites in this embodiment can calculate the mutual distance between adjacent two satellites and transmit to the observation point a signal concerning the calculated mutual distance, and comprises a clock means calibrated by a signal sent from the control station, a means responsive to the calibrated clock means for transmitting the reference signal to the observation point and a means for transmitting the received reference signal to the observation point and the subsequent satellite.

In another embodiment of the invention, five or more satellites are disposed on a stationary orbit having the orbit inclination angle of substantially 6-10 degrees; (a) a synthesized signal including a time signal designating a transmission time and a reference signal synchronized with the time signal is transmitted from any one of four adjacent satellites to the observation point and one of the subsequent three satellites, the four satellites being disposed to be simultaneously in the range of vision of the observation point such that the anomalies of the four satellites are separated from one another substantially at an angle of 120 degrees; (b) each of the remaining three satellites transmits a new synthesized signal including the reference signal in the received synthesized signal and a time signal designating a time at the satellite, to the observation point and the subsequent satellite; (c) the times of reception of the signals transmitted from the four satellites are determined at the observation point; (d) the positions of the four satellites are calculated by using the determined times and estimated values of the orbit position obtained from a control station on the earth; and (e) three hyperboloids each placing the foci on adjacent two of the calculated positions of the four satellites are determined, whereby the position of the observation point is determined as an intersecting point of the hyperboloids.

Each of the satellites of this embodiment comprises a clock means calibrated by a command signal sent from the control station, a means for generating a reference signal for distance measurement, a means for producing a synthesized signal by synthesizing outputs from the clock means and the generating means, a means for transmitting the synthesized signal to the observation point and the subsequent satellite, and a means for transmitting the received synthesized signal to the observation point and the subsequent satellite.

The command signal is produced on the basis of the time signal contained in the synthesized signal received by the observation point, the orbit and the estimated positions of the four satellites and the standard time.

In a further embodiment of the invention, four satellites are disposed on a stationary orbit having orbit inclination angle of substantially 6 degrees; (a) a synthesized signal including a time signal designating a transmission time and a reference signal synchronized with the time signal is transmitted from any one of adjacent three satellites to an observation point on the earth and one of the remaining two satellites, the three satellites being disposed to be simultaneously in the range of vision of the observation point such that the anomalies of the three satellites are separated from one another substantially at an angle of 120 degrees; (b) each of the remaining two satellites transmits a new synthesized signal including the reference signal in the received synthesized signal and a time signal designating a time at the satellite, to the observation point and the subsequent satellite; (c) the above steps (a) and (b) are repeated after the lapse of a period having a significance to detecting the positions of the three satellites; (d) the times of reception of the signals transmitted from the three satellites in the above steps (a) and (b) are determined at the observation point; (e) the positions of the three satellites when they perform the operations in the steps (a) and (b) are calculated by using the determined times and estimated values of the orbit position obtained from a control station on the earth; and (f) three hyperboloids are determined each placing the foci on adjacent two of the calculated positions of the three satellites, whereby the position of the observation point is determined as an intersecting point of the hyperboloids.

Each of the satellites in this embodiment comprises a clock means calibrated by a command signal sent from the control station; a means for generating a reference signal for distance measurement, a means for producing a synthesized signal by synthesizing outputs of the clock means and the generating means, a means for transmitting the synthesized signal to the observation point and the subsequent satellite, and a means for transmitting the synthesized signal from the preceding satellite to the observation point and the subsequent satellite.

The command signal is produced on the basis of the time signal contained in the synthesized signal received by the observation point, the orbit and the estimated positions of the respective satellites and the standard time.

In accordance with the present invention, as far as an observation point is not in the polar regions locating at high latitudes, an observer can calculate his own position using a simple clock and a receiver equipped with an algorism for calculation processing.

Other objects and features of the present invention will more clearly be understood by those skilled in the art who read the following detailed description with reference to the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is an illustration showing the disposition of satellites in a conventional GPS;

FIGS. 2 and 3 are illustrations for explaining a method of determining the position of an observation point using two satellites;

FIGS. 4 and 5 are illustrations for explaining a method of determining the position of an observation point using three satellites;

FIGS. 6 and 7 are illustrations of the first embodiment of a method of determining the position of an observation point using four satellites in accordance with the present invention;

FIG. 8 is an illustration diagrammatically showing the disposition of the four satellites and the observation point in the first embodiment;

FIG. 9 is a diagram showing an algorism for calculating the position of the observation point according to the present invention;

FIG. 10 is an illustration showing the positional relationship between the range of vision of the observation point and the satellites disposed on a stationary orbit in the first embodiment;

FIG. 11 is an illustration showing the orbit inclination angle of the stationary orbit of the satellites in the first embodiment;

FIG. 12 is an illustration showing the relative positions and the loci of the four satellites which are simultaneously in the range of vision of the observation point in the first embodiment;

FIG. 13 is an illustration showing the times at which electrical waves transmitted from a satellite reach the observation point directly or by way of the remaining satellites in the first embodiment;

FIG. 14 is an illustration for explaining a method of calculating the mutual distances among three satellites;

FIG. 15 is an illustration for explaining a method of determining the mutual distance between two satellites in consideration of their movements;

FIGS. 16(a), (b) and 17 are illustrations showing a signal transmission procedure among three satellites and between the respective satellites and the observation point in the first embodiment;

FIG. 18 is an illustration showing a procedure of sequentially calculating the distance differences between the satellites and the observation point;

FIG. 19 is an illustration for explaining a method of calibrating clocks equipped in the satellites by a control station on the earth according to the present invention;

FIG. 20 is a block diagram showing the arrangement of a transmission section equipped in the satellites according to the present invention;

FIG. 21 is an illustration of the format of a signal transmitted from the transmission section of FIG. 20;

FIG. 22 is an illustration showing the movements of two satellites on the orbit;

FIGS. 23(a), (b) and (c) are illustrations showing the structures of signals received at the observation point when a signal in the format of FIG. 21 reaches the observation point directly and through a satellite;

FIGS. 24 and 25 are illustrations for explaining the second embodiment of a method of determining the position of an observation point using three satellites according to the present invention;

FIG. 26 is an illustration showing the relationship between an observation point and the positions of three satellites at two different times in the second embodiment;

FIG. 27 is a diagram showing an example of the arrangement of a satellite capable of transmitting a reference signal to the observation point and communicating with adjacent satellites in accordance with the present invention;

FIG. 28 is an illustration of a modified arrangement of the satellite of FIG. 27;

FIG. 29 is an illustration showing another example of the arrangement of a satellite capable of transmitting a signal generated by synthesizing a time signal and a distance measurement signal; and

FIG. 30 is an illustration of a modified arrangement of the satellite of FIG. 29.

Throughout the figures, similar or like elements and components are designated by the same numerals and symbols.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Principle of Measurement

The principle of measurement for determining a position of a point on the earth using a plurality of satellites will first be described to give a better understanding of the present invention.

FIG. 2 illustrates how a two-dimensional position is determined using two satellites. Let's assume that satellites 1 and 2 on an orbit are at points A and B, respectively. The reference numeral 3 is the x-axis passing through these satellites; 4 the y-axis having its origin as the mid-point on the x-axis between the satellites; P a point at which a difference between the distances AP and BP is constant; 5 a hyperbola which is a locus of the point P on the x-y plane; and 6 another hyperbola symmetrical to the hyperbola 5 in respect to the y-axis.

The hyperbolae on the x-y plane are expressed by the following formula: ##EQU1## where, the focus f and the eccentricity e are expressed as follows: ##EQU2##

The difference between the distances AP and BP d=2a₁.

In the present invention, measurements are made on the difference between the distance between the satellite 1 and the observation point P and the distance between the satellite 2 and the observation point P. With the arrangement of FIG. 1, the hyperbolae 5, 6 can be depicted by such distance difference information. The observation point exists on either of the hyperbolae 5, 6, and it is possible to determine on which of the hyperbolae the observation point P exists if one obtains information on the relative length of the distances AP and BP. In this instance, the observation point exists on the hyperbola 5.

Although the two-dimensional case has been described with reference to FIG. 2, the real phenomena are three-dimensional. A hyperboloid 7 as shown in FIG. 3 depicted by turning the hyperbola 5 about the x-axis will next be considered.

FIG. 3 illustrates the hyperbola in the x-y-z coordinate system. The reference numeral 8 is the x-axis; and 9 and 10 cross-sections of the hyperboloid 7 taken along planes, respectively, parallel to the y-z plane.

The hyperboloid 7 can be obtained by the following formula: ##EQU3##

In the case shown either in FIGS. 2 or 3, if the point P is on the x-axis, the hyperbola 5 and hyperboloid 7 may become straight lines. However, such arrangement can not exist because the satellites are on a stationary orbit and the observation point is on the earth.

An example using three satellites will now be described by reference to FIG. 4. A further satellite 20 is added at a position C in another x'-y' coordinate system existing in the x-y plane of FIG. 2. The reference numeral 21 is the x'-axis passing through points A and C; 22 the y'-axis passing through the mid-point between A and C; θ an angle formed between the x- and x'-axes; 23 a hyperbola depicted on the basis of the fact that the difference between the distances AP and CP is constant; 24 and 25 points of intersection of the hyperbolae 5, 23; and 26 a straight line passing through the points 24, 25.

The observation point P exists at a location which satisfies the condition that the difference between the distances AP and BP is constant and that the difference between the distances AP and CP is constant. It is at two points, i.e., the intersecting points 24 and 25 where the same distance difference can be measured both on the hyperbolea 5 and 23.

The phenomenon in the x-y and x'-y' planes which has been considered with reference to FIG. 4 will now be developed to a three-dimensional phenomenon in x'-y'-z' coordinate system. The reference numeral 27 is a hyperboloid obtained by rotating the hyperbola 23 about the x'-axis; 28 a plane including a line segment passing through the intersecting points of the hyperboloids 7 and 27; 29 the z'-axis; and 30 a curve of secondary degree formed by the intersection between the hyperboloids 7 and 27.

The hyperboloids 7 and 27 in the x-y-z and x'-y'-z' systems are expressed by the following equations: ##EQU4##

The relation between the x-y-z and x'-y'-z' systems are as follows: ##EQU5## e: eccentricity.

Since the x-y and x'-y' planes are on the same plane,

    z=z'                                                       (6)

When eliminating z from Equations (2) and (4) using Equation (6), ##EQU6##

It is known from the hyperbola formula that the ratio of the length between a point on a hyperboloid and the focus to that between the point on the same hyperboloid and the directrix is equal to the eccentricity. In the x-y and x'-y' planes shown in FIG. 4, the hyperbola 5 is in the first and fourth quadrants and the hyperbola 23 is in the second and third quadrants, thereby providing the following expression:

    AP=|e.sub.1 x-a.sub.1 |-|e.sub.2 x+a.sub.2 |                                                (8)

If considering the sign in the case of FIG. 3, Equation (8) can be as follows:

    e.sub.1 x-a.sub.1 =-(e.sub.2 x+a.sub.2)                    (9)

The relation expressed by Equation (9) is not only established in the x-y and x'-y' planes, but also in the hyperboloids of FIG. 5. When Equation (7) is substituted for by Equation (9) to develop an equation for obtaining the condition under which the hyperboloids intersect, the following linear equation can finally be obtained:

    K.sub.1 x+K.sub.2 y+K.sub.3 =0                             (10)

where

K₁ =-2a₂ (e₁ +e₂ cos θ);

K₂ =-2e₂ a₂ sin θ; and

K₃ =e₁ ² a₁ ² +2e₁ e₂ a₁ a₂ cos θ+e₂ ² a₂ ² -(a₁ -a₂)² -(b₁ ² -b₂ ²).

Equation (10) is independent of z and z', and there is a plane 28 parallel to the z and z' axes and common to the x-y-z and x'-y'-z' systems. The intersecting points 24, 25 of Equations (2), (4) are on the plane 28.

In the configuration of FIG. 5 using the three satellites, it is appreciated that the observation point P is on a circle or ellipse, a curve of secondary degree existing on the plane 28. If the altitude of the point P can be obtained as a known value from another system, the point P will be determined. However, three satellites are insufficient to determine the point P as one point from information of the difference between the distances between the satellites and the observation point.

First Embodiment

FIG. 6 shows a method of determining a two-dimensional position of a point on the earth using four satellites. The fourth satellite 40 is in a position D. The reference numeral 41 is the x"-axis passing through points C and D; 42 the y"-axis passing through the mid-point between C and D; 43 a hyperbola placing the foci on position C of the satellite 20 and position D of the satellite 40; 44 an angle between the x' and x" axes; and 45 a line passing through the intersecting points of the hyperbolae 5 and 43.

As a result of adding the new x"-y" coordinate system and the new satellite 40 to the system shown in FIG. 4, a constant difference between the distances between a point and the satellites 20, 40 can be observed, and thereby the hyperbola 43 is depicted. The line 45 passing the intersecting points of hyperbolae 5 and 43 can be obtained, which enables the point P to be determined at the intersecting point of two lines 26, 45. In the two-dimensional plane, the observation point can be determined as the junction of two lines using four satellites.

A similar concept can be applied to a three-dimensional system. This will now be described with reference to FIG. 7 in which the reference numeral 46 is the z"-axis of x"-y"-z" system, and 47 indicates a plane of intersection between the hyperboloid 7 and a hyperboloid formed by rotating the hyperbola 43 about the x"-axis.

As described in respect of FIG. 5, the plane 28 can be depicted on the basis of the position of the satellites 1, 2, 20 in the x-y-z and x'-y'-z' systems, and the plane 47 can also be depicted on the basis of the positions of the satellites 1, 20, 40 in the x-y-z, x'-y'-z' and x"-y"-z" systems. The observation point exists on a curve of secondary degree 48 common to the two planes 28 and 47, and also at a point of intersection of these two planes.

The plane in which the point P exists can be obtained algebraically using Equation (10), but in the case of FIG. 7, it is difficult to obtain the point P using any algebraic expression, and so the characteristic solution is obtained by numerical analysis.

The dispositions of the satellites 1, 2, 20, 40 and the observation point P is shown in FIG. 8. The positions A, B, C, D of the satellites 1, 2, 20, 40 and the point P are indicated by the following coordinates. ##EQU7##

The coordinates of the point P are unknown numbers to be obtained. The values to be observed are the following three: ##EQU8##

Based on Equation (13), the following difference equation is obtained; ##EQU9##

The function f(x, y, z) has a single minimum value at the point P. In order to determine such point, calculation is repeatedly performed using the steepest inclination method and an initially predicted observation point as the initial value so that the minimum value for the point P can numerically be calculated.

An algorithm of the numerical calculation is shown in FIG. 9. At the step 50, the initial value (x_(o), y_(o), z_(o)) is set such that the value is not so much spaced away from the observation point. In this case, a value is preset for ceasing the repeated calculation when the difference between the calculated value of the function f(x, y, z) and the value obtained by substitution with the observed values becomes minimal. At the step 51, the calculation is initiated from k=0. At the step 52, Equation (14) is calculated when (x_(k), y_(k), z_(k)). At the step 53, ε is compared with the value calculated at the step 52, and if f(x_(k), y_(k), z_(k)) is smaller than ε, the repeated calculation is ceased, and (x_(k), y_(k), z_(k)) is output at the step 54. At the step 55, the partial differentials of the x, y, z components are calculated to obtain the differential coefficients. At the step 56, a numerical value is calculated for determining the magnitude of movement when moving from the k-th point to the (k+1)-th point. This value is set such that a value a_(k) indicating the rate of variation in the movement varies with a large width while f(x_(k), y_(k), z_(k)) has a large value, and takes a small width and converges to the extremal value when f(x_(k), y_(k), z_(k)) approaches the extremal value. It is a useful measure to search the extremal value by calculating the values of Equation (14) before and after the point (x_(k), y_(k), z_(k)). At the step 57, a_(k) is multiplied by the differential coefficients calculated at the step 54 to obtain the amount of movement of the respective components. Since the differentiated value in the direction existing the extremal value has a larger value, the vector value consisting of the three components can approach the extremal value by way of the shortest path when k is replaced with (k+1). (x_(k), y_(k), z_(k)) minus the k-th amount of movement is newly set as (x_(k+1), y_(k+1), z_(k+1)). At the step 58, k is incremented by 1. The calculation is repeated until the decision condition at the step 53 is attained, and when exceeding the decision value, (x_(k), y_(k), z_(k)) is obtained as an output.

The positions of the satellites on the orbits will now be described. The satellites are on a stationary orbit and the present invention employs an orbit inclination angle larger than the small angle (for example, 0.05 degrees) employed in ordinary satellites. With this, it can be avoided that the satellites align at the same time.

In the present invention, it is necessary that four satellites are always visible from the observation point. They are desirably at higher angles of elevation so that the range of vision is not obstructed by a building or the like, but this causes the number of satellites to increase. FIG. 10 shows a state of satellites on a stationary orbit 60 when viewed from a point above the north pole of the earth 61.

The reference numeral 62 is the horizon at the observation point P; and 63 is a line extending through the earth's center O and the stationary orbit and intersects the orbit 60 at a point Q. The angle of elevation at the point P is designated by θ₂ ; the angle between OP and OQ by θ₁ ; the normal line from Q by H; the angle between PQ and QH by θ₃ ; and the radius of the earth by r. The reference numerals 70, 71, 72, 73, 74 and 75 are satellites on the stationary orbit 60.

With respect to ΔPQH, the following equation is obtained: ##EQU10## Since QH and the horizon 62 are parallel to each other, the angle of elevation can be obtained by θ₂ =θ₃.

Table 1 shows the relation between the angle of elevation and the number of satellites in the case where four satellites are between OQ and OQ' (Q' being the symmetrical point of Q) that is, in the visible range of the observation point. If the angle of elevation is about 9 degrees which may be an appropriate value, then the number of satellites needed is 10.

                  TABLE 1                                                          ______________________________________                                         Angle of Elevation                                                                              Number of Satellites Needed                                   ______________________________________                                         1.3      degrees      9                                                        9.3                  10                                                        16.1                 11                                                        ______________________________________                                    

The orbit inclination angle will now be described. It is necessary to select the orbit inclination angle so that the latitudinal distance of the satellites from the equatorial plane is significant for measurements relative to the distance between the satellites. If the orbit inclination angle is too large, however, the angle of elevation can not be large in high-latitude areas. The resident areas of the earth range almost between the north and south latitudes of 65 degrees. The relation between the angle of elevation and the orbit inclination angle at the latitude of 70 degrees is shown in Table 2.

                  TABLE 2                                                          ______________________________________                                                  Angel of   Distance from Equatorial Plane                             Latitude Elevation  (one side)                                                 ______________________________________                                         70 degrees                                                                              5 degrees  5,689 km                                                   65 degrees                                                                              5 degrees  8,534 km                                                   65 degrees                                                                              10 degrees 4,759 km                                                   ______________________________________                                    

FIG. 11 shows the relation between the latitude and the satellite movement. The latitude of the observation point P is designated by θ₄, and the angle of elevation as viewed from the point P by θ₅. The reference numeral 80 is the equatorial plane; and 81 a line orthogonally intersecting the stationary orbit existing on the equatorial plane 80. The horizon 82 and the equatorial plane 80 intersect at T; the equatorial plane 80 and a line forming the angle of elevation θ₅ with respect to the line PT intersect at U; the equatorial plane and the stationary orbit intersect at V; and the extension of the line segment PU and line 81 intersect at W.

When the latitude θ₄ and the angle of elevation θ₅ are given, the following angles are determined:

    ∠PTO=90°-θ.sub.4 =θ.sub.6

    ∠PUT=180°-θ.sub.5 -(180°-θ.sub.6)=θ.sub.6 -θ.sub.5 =θ.sub.7

When the sine rule is applied to ΔPUT, ##EQU11## Further, ##EQU12##

    then

    VW=UV tanθ.sub.7                                     (18)

Table 2 shows the latitude of the observation point and the distance of the satellite from the equatorial plane when the satellite in the equatorial plane is viewed from the observation point in the due south or due north direction.

In the present invention, four satellites should be distributed on a plane when viewed from the observation point, and these satellites should not exist on the same line.

FIG. 12 shows the positions and loci of four satellites when viewed from the observation point.

At a certain time the four satellites are in positions 91, 92, 93, 94. These satellites are disposed such that the anomalies of the adjacent satellites are separated substantially 120 degrees at the same point of time. In other words, the positions of the satellites 91, 92, 93, 94 respectively correspond to points 101, 102, 103, on a circle 100. When a certain time has elapsed, the satellites move to positions 91'-94' which respectively correspond to points 101'-103'. The respective satellites depict loci 105-108. Although the loci 105-108 are shown in straight lines in the figure, these loci show in reality what is called the 8-figure characteristic.

In FIG. 12, the adjacent satellites are connected by dash and dotted lines. The dash and dotted lines appropriately bend and the four satellites distribute in a large area.

The present invention is based on measuring the difference between the distances between two satellites and the observation point. Exemplifying the satellites 1 and 2 of FIG. 8, the distance difference between AP and BP is to be measured. For the purpose of measurement, the satellites 1, 2 generate signals at the same time, the signals are received at the observation point P and the difference in arrival time of the two signals are measured, thereby determining the above-stated distance difference. This method is practicable if the satellites 1, 2 have clocks indicating the same time. On the other hand, the present invention deals with a case in which the satellites have clocks indicating different hours. The signal generated by the satellite 1 reaches the observation point P directly and by way of the satellite 2. From the arrival times of such signals, the difference between AP and AB+BP is measured. AB can be calculated by the satellite communication or on the basis of the position of the two satellites. The subtraction of AB from the measured AB+BP allows the determination of the distance difference between AP and BP.

A similar way of thinking can be expanded to the case of four satellites 1, 2, 20 and 40. The satellite 1 acts as a source and generates a signal which travels through the paths AP, ABP, ABCP, ABCDP to the observation point P and the time required for travel is roughly estimated for each path.

In the case of transmission of signal through the path of A-B-C-D-P, assume that the satellite distance is 31,500 km [≈√26400² +(8600×2)² ], and that there are four satellites on the stationary orbit, each being latitudinally spaced by 8,600 km away from the equatorial plane with a relatively large orbit inclination angle and the satellites being spaced in the maximum distance. In practice, however, all the inter-satellite distances are not at the maximum. Then, the maximum value of the distance ABCDP is shown below.

    (ABCDP).sub.max =31,500×3+36,000=130,500             (19)

Since the velocity of light is 3×10⁸ m/sec, the time required for the signal to transmit through (ABCDP)_(max) is given below. ##EQU13##

On the basis of the above-described conditions, a method of determining the position of the observation point will be described with reference to FIG. 13. The abscissa shows the time and the ordinate shows paths. The satellite 1 generates a reference pulse 111 at time T₀, and the pulse is then received as a pulse 112 by the observation point P at time T₁. The reference pulse passing the satellite 2 is received by the point P as a pulse 113 at a time T₂ ; the reference pulse passing the satellites 2 and 20 is received by the point P as a pulse 114 at a time T₃ ; and a reference pulse passing the satellites 2, 20 and 40 is received by the point P at a time T₄.

The distance differences required to calculate the hyperboloids for position detection are obtained as follows: ##EQU14## where, C is the velocity of light. Equation (21) means that three distance differences can be determined if the distances AB, BC, CD and the times T₁ to T₄ are measured, and that the point P can be determined as a point of intersection of three hyperboloids placing the foci on the points A and B, A and C, and C and D, respectively.

There is no need to provide any accurate clock at the observation point. When the satellite 1 generates the reference pulse 111 at a predetermined reference time T₀, for example, at an integral-second time, the observer, who can roughly estimate the positions of the satellites, reads, with a clock having the accuracy of the order of 0.1 seconds, the reception times T₁, T₂, T₃ and T₄ of the reference pulses passing through the satellites 2, 20, 40 and accurately determines the time T₀ at which the reference pulse was initially generated. The observer can calibrate an ordinary clock by receiving time information from JJY and obtains the absolute time with the accuracy of the order of 0.1 seconds. Thus, the measurements are performed between times T₀ and T₄, as shown in FIG. 13, and the measuring process can be completed for less than 1 second including a processing operation required. If the reference pulses are generated by the satellite 1 at the time intervals of 2 seconds, the time when the satellite 1 generates the reference pulses can be determined at the observation point P without uncertainty.

In order to determine the distances AB, BC, CD, it is necessary that the positions of satellites on the orbit are precisely known. The control station is operable to measure the distance of the satellites and the rate of change in the distance. Accordingly, it is feasible to perform orbit calculations on the basis of the data obtained by the control station to decide the orbit, which enables the future positions of the satellites to be estimated. The estimated values of the orbit can be obtained as a function of time. Thus, when the times T₀ to T₄ are determined, the positions of the respective satellites are obtained and the distances AB, BC, CD can be determined.

In the case ten satellites exist on the stationary orbit 60 shown in FIG. 10, every three of them are grouped, and one of the satellites in one group first generates a reference signal at an integral-second time and a satellite in the subsequent group generates a reference signal integral seconds, such as one or two seconds, after the signal generation of the preceding satellite group. At the observation point P, necessary data can be obtained by observing four satellites of those in two groups. More specifically, the ten satellites a, b, c, d, e, f, g, h, i and j are grouped into four groups (a, b, c), (d, e, f), (g, h, i) and (j), and satellites a, d, g respectively generate reference signals at integral-second times. The subsequent combination (b, c, d), (e, f, g), (h, i, j) and (a) is next formed. Four satellites of those in two groups, for example, (a, b, c), (b, c, d) are within the range of vision of the observation point P, and with the reception of the signals from these four satellites the position of the observation point P can be determined.

Alternatively, reference signals are generated by forming another combination (a, b, c, d), (e), (f, g, h, i) and (j). The satellites a and f generate reference signals at integral-second times and the remaining satellites in each group receive the signals from the satellite a or f and then transmit the received signal to the observation point P and the subsequent satellites.

The position of the point P can be calculated on the basis of receiving signals from four satellites. Reference signals are then transmitted from the satellites b and g of a subsequent combination (b, c, d, e), (f), (g, h, i, j) and (a) at integral-second times, and the combination of satellites is successively changed in order to enable different observation point to determine their positions.

The mutual distance between the satellites can be calculated not by the orbit estimation but by direct measurement of the position of the satellites. This will be described with reference to FIG. 14. With respect to the satellites 1, 2 and 20 at positions A, B and C, respectively, the following measurements are performed: ##EQU15## where the distances between A and B, A and C, and C and B are designated by α, β and γ, respectively. By solving Equations (22), the following equations are obtained: ##EQU16## A device for measuring the inter-satellite distance is mounted in each of the satellites 1, 2 and 20, and inter-satellite communication is performed between the satellites so that the distances between them can be measured. More specifically, a signal is generated from the satellite 1. The satellite 20 receives the signal directly from the satellite 1 and the same signal coming by way of the satellite 2. The difference between the times of reception of these signals leads to the determination of the difference in distance δ₁. Such determination is performed by the similar measurement in the respective satellites to determine δ₁, δ₂, δ₃ of Equations (23). The measured values δ₁, δ₂, δ₃ are transmitted as telemetry data to the observation point and the control station.

Since the distances α, β, γ between the satellites are determined by solving Equations (23), the time required for the signal to propagate between two satellites can be calculated. This means that the time during which the reference signal passes through the respective satellites 2, 20 can be determined by the time at which the satellite 1 generated the signal, and the positions of the respective satellites can accurately be determined.

In this manner, the distances AB, BC and CD of Equations (21) can be determined to allow accurate hyperboloids to be depicted.

It should, however, be noted that the distances AB, BC, CD should be determined taking the movements of the satellites into consideration. This will be described with reference to FIG. 15 in which the reference numeral 120 is the direction of movement of the satellite 1; and 121 the orbit of satellite 2. The positions A and B of satellites 1 and 2 at a reference time T₀ can be determined by the orbit estimation. At time T₀, the satellite 1 delivers a reference pulse to the satellite 2. Since the satellite 2 is moving on the orbit 121 as time passes, it receives the reference pulse from the satellite 1 at a point L. The time required for the satellite 2 to move from the point B to the point L is equal to the time required for the reference pulse to propagate from the satellite 1 to the point L. Thus, AL/C=difference between the time when the satellite 2 is at the point L and the time when it was at the point B, where C is the velocity of light.

Since only the point L satisfies such condition, the point L and the distance AL can be determined. Although Equations (21) do not include any component relating to the movements of the respective satellites, when taking such movement into consideration, AL obtained should be used in place of AB.

On the basis of the above description, a procedure for determining the difference between the distances between the satellites and the observation point will concretely be described. It is noted that each of the satellites is provided with a device for measuring the mutual distance, as described in reference to FIG. 14. FIGS. 16(a) and 16(b) show a procedure of signal transmission among three satellites and between the respective satellites and the observation point.

FIG. 16(a) shows one group consisting of three satellites 1, 2 and 20, the satellite 1 being a signal source, and FIG. 16(b) shows another group including satellites 42, 42' and 42" operable in the same way. The flow of signals of one group will be described with reference to FIG. 17.

From the satellite 1 at the position A, an original signal 141 (FIG. 17) is transmitted at time T₀ towards the observation point P through a path 130 and toward the satellites 2, 20 through paths 131 and 132. The reason why the satellite 1 sends the original signal to the satellites 2, 20 will be explained later. The observation point P then receives a signal 142 at time T₁₁. The signal generated by the satellite 1 and passing through the satellite 2 is transmitted through a path 133 and received as a signal 143 by the observation point P at time T₁₂. By measuring the time difference (T₁₂ -T₁₁), the distance difference ABP-AP can be determined as follows:

    ABP-AP=C(T.sub.11 -T.sub.12)                               (24)

Since the distance AB is determined by the estimated positions of the satellites 1, 2 or by actual measurements, the difference between AP and BP can be determined by subtracting AB from the result of Equation (24).

    BP-AP=C(T.sub.11 -T.sub.12)-AB                             (25)

Similarly, the satellite 2 sends a signal through the path 133 to the observation point P and through paths 136, 137 to the satellites 2, 20, and the observation point P receives a signal 143 coming through the path 133 at time T₁₂ and a signal 144 passing through paths 137, 135 at time T₁₃. Thus,

    BP-CP=C(T.sub.13 -T.sub.12)-BC                             (25')

The measurement of the mutual distances among the satellites 1, 2 and 20 will now be described. As described above, the satellite 1 transmits the signals towards the satellites 2 and 20 through the paths 131 and 132. Then the satellite 2 transmits the received signal toward the observation point P through the path 133 and towards the satellite 20 through the path 134. The satellite 20 receives the signals at times T₁₄, T₁₅ and the time difference between T₁₄ and T₁₅ enables the difference between the paths of two signals ABC and AC to be measured:

    ABC-AC=C(T.sub.15 -T.sub.14)                               (26)

    γ+α-β=δ.sub.1                       (27)

where δ₁ =C(T₁₅ -T₁₄). With the signals passing through the paths 132, 137 and the signal passing through the path 131, the following relation is established:

    ABC-AB=C(T.sub.17 -T.sub.16)                               (28)

    γ+β-α=δ.sub.2                       (29)

where δ₂ =C(T₁₇ -T₁₆). With the signals passing through the paths 136, 132 and the signal passing through the path 134, the following relation is also established:

    BAC-BC=C(T.sub.19 -T.sub.18)                               (30)

    β+α-γ=δ.sub.3                       (31)

where δ₃ =C(T₁₉ -T₁₈). Using Equations (27), (29) and (31), the distances α, β, γ between the satellites are determined.

For the satellites 42, 42' and 42", the same measuring procedure as for the satellites 1, 2 and 20 can be applied to. In the arrangement of FIGS. 16(a) and 16(b), the satellite 1 and 42 operate as the origins of signal and transmit the signals at reference times.

In case where there are, for example, ten satellites a, b, c, d, e, f, g, h, i and j on an orbit, a combination C₁ of four satellite groups (a, b, c), (d, e, f), (g, h, i) and (j) is formed to make such measurement of time differences as described with reference to FIGS. 16(a), 16(b) and 17. The measurement of distance difference is similarly made with respect to the subsequent combination C₂ (b, c, d), (e, f, g), (h, i, j) and (a). Thus different four groups are successively formed to make subsequent measurements. The observation point P makes the measurements with respect four satellites included in two groups, such as (a, b, c) and (b, c, d), and obtains all the information required to detect the position of the point P. FIG. 18 shows a procedure of sequential measurements of distance differences on ten satellites grouped into four groups. At a time τ₁, the period for a first measurement of distance difference on four groups (a, b, c), (d, e, f), (g, h, i), (j) of the first combination C₁ is initiated and completed about 0.5 seconds later. The period for a second measurement on groups (b, c, d), (e, f, g), (h, i, j), (a) of the second combination C₂ continues for about 0.5 seconds from the time τ². A third measurement on groups (c, d, e) (f, g, h) (i, j, a), (b) of the third combination C₃ starts at the time τ₃ and continues for about 0.5 seconds. Such measurements are repeated in such an order as shown in FIG. 18.

As described above, the clock located at the observation point P is calibrated in accordance with the primary time standard of the country, such as JJY. Since four satellites, according to the present invention, are positioned in the range of vision of an observation point, it is feasible that the control station always observes the time at the respective satellites and precisely calibrates the clocks of the satellites.

Thus, the satellites can have highly precise clocks. Since the control station can know an accurate time from the primary time standard of the country, the time control can be achieved by cooperatively operating the primary time standard, control station and satellites. More specifically, a satellite sends to the control station a time signal indicating the current time at that satellite. The control station receives the time signal from the satellite, corrects the time signal using the time delay caused during the propagation of the signal and determined from the orbit information of the satellite possessed by the control station, and compares the corrected time signal with the time on the group system. In FIG. 19, it is assumed that a time signal indicating that the clock of the satellite a points to a reference time t₁ is received by the control station at a time t₂. In contrast, the clock of the control station points to the time t₁ at a time t₃ and the control station estimates, on the basis of orbit estimation values, that the signal delivered from the satellite a at the reference time will be received at a time t₄. Thus, when the control station detects the time difference t₄ -t₂, the station sends a command to the satellite a to cause the clock of the satellite a to be calibrated. With this, the satellite can have a highly accurate clock.

Such clock calibration is not need to be performed every time when the time signal comes from a satellite. Instead, the time difference may be successively detected over a certain length of time and stored, and when the stored value exceeds a predetermined value, the calibration is performed to the clock of the satellite. This will facilitate the detection of the time difference.

Since the clock mounted on the respective satellite is, as described above, precisely calibrated, the satellite can transmits to the observation point P a signal including formation indicating the delivery time of the original signal. Thus, the observation point can obtain information necessary for measuring the distance differences including the time of generation of the original signal, thereby determining the accurate positions of the respective satellites.

In the arrangements thus far described, pulses are transmitted between the satellites and the observation point and among the satellites. The distance measurement using pulses has broadly been utilized in the radar art. If a pulse generating equipment is installed on the group it is easy to generate pulses having high amplitudes, but most of such pulses can only reach up to at most about 1,000 km. In the cosmic space, however, the range of signal is extremely large, and, moreover, instantaneously focusing a signal energy in a pulse-like shape for distance measurement disadvantageously enlarges the size of the equipment. If a signal designating the time is transmitted over a long period of time and an apparatus with which detection of such a signal can be performed for a long period of time is adopted on a receiving side, the arrangement of equipment to be positioned in satellites can be simplified.

The maximum distance of signal transmission required for measurement is about 130,500 km, as obtained by Equation (19), and coding should be performed such that only one unambiguous code exists in this distance. If a basic signal block is of the frequency 1 MHz, about 0.43×10⁶ repeated wave forms exist therein. If 20-bit shift register is used to generate the psudo-random code (PRN code), 1×10⁶ (≈2²⁰ -1) characteristic patterns can be formed. Alternatively, 1023×1023≈1×10⁶ characteristic patterns can be generated by allowing the phase of the PRN code generated from two 10-bit shift registers to be characteristic and using the gold code obtained by the logical Module 2 addition. On the reception side, correlation between two signals having time differences is operated to measure a difference in phase between the two codes, or the distance difference. This principle of measurement can be applied to the measurements of distances between the observation point and a satellite as well as between satellites. Such measurements will be made by a method using pulses if a laser communication is developed further. Using the PRN code will bring about advantages in that a plurality of different PRN codes, though having the same frequency, can simultaneously be used and that the power density required in view of the electric wave interference can easily be maintained.

It is possible to obtain full information of the distance difference for determining the position of the observation point P by using the above-described PRN code and causing each satellite to simultaneously transmit a distance measurement signal and a time signal to the observation point and a subsequent satellite.

This will be described with reference to FIG. 20 which is a block diagram showing the arrangement of a transmitter mounted in a satellite for simultaneously transmitting the distance measurement signal and the time signal. In this figure, the reference numerals 160 and 161 are shift registers for generating PRN codes for distance measurement; 162 a time signal generator; 163 a timer device; 164 a carrier wave generator; 165 a clock signal for controlling the timing of generation of the PRN codes and the time code; 166 a reset signal for resetting the registers 160, 161 at an integral-second time; 167 a MOD-2 adder of two codes; 168 and 169 modulators; 170 a 90-degree phase shifter; and 171 a synthesizing circuit for generating a QPSK signal.

The clock for the PRN codes is of 1 MHz, for example. The two PRN codes are MOD-2 added by the adder 167 to produce a new PRN code. The reason for the necessity of the distance measurement signal generated by synthesizing the two PRN codes was described above. The modulator 168 modulates the carrier with the new PRN code to produce a BPSK (Bi-phase shift keying) modulation signal.

The content of the PRN codes is reset to zero at an integral-second time and changes from that time. The time signal generator 162 delivers to the modulator 169 a time signal under the control of the clock signal 165, the time code signal indicating the current time read from the timer device 163 when the reset signal 166 is input. With the time signal, the modulator 169 modulates the carrier having the phase 90 degrees different from that of the distance measurement signal. The distance measurement signal and the time signal, which are orthogonally modulated, are synthesized by the synthesizer 172 to form a single QPSK signal. Thus, the observation point P can, when receiving the QPSK signal, determine the time of signal generation.

FIG. 21 shows a format of the signal transmitted from the transmitter of FIG. 20. The time signal STM and the distance measurement signal SDM continue from an integral-second time τ₀ at which the reset signal 166 is input from the timer device 163 to a time τ' when a relatively short period has elapsed from the time τ₀.

The time signal generator 162 is zero cleared at the time τ₀ and the time count is started at that time. The time signal STM includes a plurality of time codes which designate the time τ₀ and the times τ₁, τ₂, . . . , τ_(i), . . . taken at predetermined intervals of time after τ₀. The distance measurement signal SDM includes an array of PRN codes which are zero cleared at the time τ₀.

As will be apparent from FIG. 21, the distance measurement signal SDM is accompanied by the time signal STM so that the observation point P can determine the time of transmission of that distance measurement signal.

Signals STM and SDM are zero cleared at intervals of several seconds or of (an integer+0.5) seconds. Since the distance measurement signal is usually shorter than the time signal, a dummy signal is inserted after the end of the last distance measurement signal.

Signals transmitted between two satellites and between them and the observation point will concretely be described with reference to FIGS. 22 and 23(a)-23(c). In FIG. 22, satellites a and b are moving to depict loci 180 and 181, respectively, and it is assumed that the satellites a and b are at their positions AI and BI, respectively, at the time τ₀ (FIG. 21).

At the time τ₀, the satellite a begins to transmit an original signal SA to the satellite b and the observation point P, and thereafter continues the signal transmission. The satellite a reaches a position Ai at a time τ_(i). The original signal SA therefore comprises a time signal STM including a series of time codes designating the times τ₀, τ₁, τ₂, . . . , τ_(i), . . . , and a distance measurement signal SDM including a series of PRN codes having phases corresponding respectively to the times τ₀, τ₁, τ₂, . . . , τ_(i), . . . and a dummy signal. The observation point P begins to receive the original signal SA as a signal SAP at a time after the transmission delay d₁ between AI and P from the time τ₀. On the other hand, the original signal SA which was transmitted from the satellite a at the time τ₀ is received by the satellite b at a position B_(i) at the time τ_(i), and then the received signal is transmitted to the observation point P. The satellite b operates such that it transmits to the observation point P the distance measurement signal of the received original signal SA as its own signal, but that the time signal of the received signal SA is replaced by a time signal including the time codes of τ_(i), τ_(i+1), τ_(i+2), . . . , τ_(i+k), . . . and then transmitted to the point P. Thus, the signal sent by the satellite b is received by the observation point P as a signal SABP at a time after the transmission delay d₂ between AI and B_(i) and between B_(i) and P. The difference between the delays d₁ and d₂ gives information on the distance difference.

The distance measurement signal S_(i) transmitted by the satellite a in its position A_(i) at the time τ_(i) is assumed to be received by the satellite b at its position B_(ik) at a time τ_(i+k). As shown in FIG. 23(b), the observation point P receives the distance measurement signal S_(i) as a portion of the signal SAP at the time T_(i). Also at this time T_(i), the observation point P receives a distance measurement signal S_(i) as a portion of the signal SABP. The difference in phase between those signals S_(i) and S_(i) ' enables detecting the difference in distance AP-BP. From a time-sequence point of view, the phase of the distance measurement signal S_(i) ' of the signal SABP will come up to the phase of the distance measurement signal S_(i) of the signal SAP after a period of time required for the signal to propagate the difference in distance AP˜ABP. Thus, when the phase difference between the signals S_(i) and S_(i) ' is determined, the propagation delay indicated by the phase difference, and therefore the data of the distance difference are obtained using the rate of the clock signal of the distance measurement system. In this case, the propagation delay can be obtained by calculation immediately after the distance measurement signal is detected by the observation point P at the time T_(i).

It may also be possible that a period of time is determined during which the phase of the distance measurement signal S_(i) ' of the signal SABP comes up to the phase of the distance measurement signal S_(i) of the signal SAP. From this period of time the distance difference is determined.

The positions of the satellites when the measurement of the distance differences are made can be obtained by reading the times of the signal reception. The time signal of the distance measurement signal S_(i) detected at the time T_(i) indicates that this distance measurement signal S_(i) was generated at the point A_(i) on the locus 180 at the time τ_(i). The point A_(i) can be determined by designating the time τ_(i) with respect to the orbit determination and orbit estimating value. Similarly, the time signal τ_(i+k) of the signal SABP also indicates the time at which the distance measurement signal S_(i) generated by the satellite a at its position A_(i) was relayed by the satellite b, and the position B_(ik) of the satellite b is definitely given through the processing of the orbit information. Thus, the hyperboloid which places the foci on the thus defined positions A_(i) and B_(i) of the satellites a and b and passed through the observation point P can be depicted.

Lets consider, as an example, the case where ten satellites a, b, c, d, e, f, g, h, i and j are positioned on an orbit and transmit the distance measurement signals and the time signals. As already described, the measurement of the distances between the satellites is performed using the inter-satellite communication function. Those ten satellites are grouped to two-satellite groups and three-satellite groups, and the combination of each group is changed as the lapse of time. For example, at an integral-second time τ, a combination C₁ (a, b, c), (d, e), (f, g, h) and (i, j) is formed and the original signals are generated by the satellites a, d, f, and i. From the time τ to an integral number of seconds from the time τ, the time signals are successively generated. The longest distance measurement signal generated from satellites a, d, f, i is shorter than the time signal, and therefore the dummy signal is inserted. The dummy signal ranges between the end of the distance measurement signal and the end of the time signal. When the measurement with the first combination C₁ has been complete, the measurement of a second combination C₂ (j, a, b), (c, d), (e, f, g), (h, i) is performed. In the case of the second combination, satellites j, c, e, h generate the original signals. In this manner, the combination of the satellite groups is changed every time an integral number of seconds has elapsed, and the measurement of the first combination starts again after 5 times of change. The observation point P can obtain distance measurement data concerning four satellites with the results of the measurements of at least two adjacent combinations.

Thus, the principle of position detection according to the present invention is that the observation point P measures the difference between the time when a signal sent directly from a satellite is received and the time when the signal relayed by way of another satellite is received. In order to make an accurate detection of the distance difference, the frequency of the distance measurement signal must be accurate and the geometrical positions of the signal sources must also be accurately known.

The observation point P receives a signal generated by a satellite as well as a signal transmitted from and relayed by another satellite. The former signal can be used as a time signal for calculating the positions of other satellites and the latter signal can be used as a distance measurement signal. It is also possible for the observation point P to make a calculation of the distance between two satellites by comparing the time information of two received signals.

According to the present invention, when two signals are simultaneously transmitted from a satellite to the observation point, it is suitable to use two frequencies, predetermined different sub-carriers or different kind of diffusion codes for the respective satellites.

Second Embodiment

The above-described embodiment is of a method of determining the position of the observation point using ten satellites disposed in the stationary orbit. Another embodiment will now be described in which eight satellites are disposed on a stationary orbit such that three of the satellites are always visible from an observation point on the earth.

As described above, it is impossible to detect the observation point only using the information of the distance differences obtained from three satellites. In this embodiment, therefore, the fact that the satellites move on the orbit with the lapse of time when viewed from the earth is used. The conditions of the orbit will be described hereinbelow.

FIG. 24 shows a two-dimensional relationship between the positions of satellites used for measurements at two difference times. Similar to the state shown in FIG. 4, the satellites 1, 2 and 20 were at the positions A, B and C, respectively, in x-y and x'-y' coordinate systems at a certain time. These satellites thereafter move to positions A', B' and C', respectively. The line passing through the points A' and B' is the x"-axis 200; the line passing through the mid-point between the points A', B' and perpendicular to the x"-axis is the y"-axis 201; the line passing through the points A' and C' is the x"'-axis 202; and the line passing through the mid-point between the points A', C' and perpendicular to the x"'-axis is the y"'-axis 203. Thus, a hyperbola 204 passing through the observation point P and placing the foci on the points A', B' and a hyperbola 205 passing through the observation point P and placing the foci on the points A', C' can be depicted. The reference numeral 206 is a line passing through the intersecting points of the hyperbolae 204, 205.

The x-y and x'-y' coordinate planes are on the same plane. Since the movements of the satellites 1, 2, 20 are three-dimensional, however, the positions A', B', C' of the satellites does not exist on the x-y and x'-y' planes. When the two-dimensional positional relation is developed to the three-dimensional positional relation, the same relation as shown in FIGS. 4 and 5 can be applied to the positions of the satellites before and after the movements, and conditions under which the plane including the x-y, x'-y' coordinates and the plane including the x"-y", x"'-y"' coordinates intersect corresponding to the movements of the satellites are established. In other words, there is a plane which includes the x"-y", x"'-y"' coordinates and intersects at a certain angle with the plane including the x-y, x'-y' coordinates, and on the x"-y", x"'-y"' coordinate systems of that plane it is possible to develop the two-dimensional relation to the three-dimensional relation as shown in FIGS. 4 and 5.

FIG. 25 shows a three-dimensional relation between the positions A, B, C and A', B' and C' of the satellites 1, 2 and 20. In this figure, the reference numeral 207 is the z"-axis and 208 is the z"'-axis. The plane including the intersecting points of the hyperboloids formed by rotating the hyperbolae 5, 23 is shown at 28, and the plane including the intersecting points of the hyperboloids formed by rotating the hyperbolae 204, 205 is shown at 209. On these planes 28, 209, quadratic curves (circles or ellipses) passing through the intersecting points of the two hyperboloids can be depicted and the observation point P exists at one of the intersecting points of these quadratic curves.

The coordinates of the positions A, B, C; A', B', C' of the satellites 1, 2, 20 and the observation point P are defined as follows:

A(x_(A), y_(A), z_(A))

B(x_(B), y_(B), z_(B))

C(x_(C), y_(C), z_(C))

A'(x_(A) ', y_(A) ', z_(A) ')

B'(x_(B) ', y_(B) ', z_(B) ')

C'(x_(C) ', y_(C) ', z_(C) ')

P(x, y, z)

Values to be observed are as follows:

    AP˜BP=S.sub.1

    BP˜CP=S.sub.2

    A'P˜B'P=S.sub.1 '

    B'P˜C'P=S.sub.2 '

Then, the following Equation (32) is solved in accordance with the same algorithm as described with reference to FIG. 9, and the position of the observation point P can be determined. ##EQU17## FIG. 26 diagrammatically shows the relation between the positions A, B, C; A', B', C' of the satellites and the position of the observation point P.

In this embodiment, it is necessary that three satellites are disposed to be always visible from the observation point. The angle of elevation of each satellite from the ground surface is desirably as high as possible in order to avoid the range of vision from being interfered by a building or the like, but in such a case the number of satellites must increase. The relation between the angle of elevation and the number of satellites positioned on the equatorial plane necessary for covering entirely the earth is shown in Table 3. If the angle of elevation is set at an appropriate angle, for example, at about 5 degrees, the number of satellites needed is 7.

                  TABLE 3                                                          ______________________________________                                         Angle of Elevation                                                                           Number of Satellites Needed                                      ______________________________________                                          5 degrees    7                                                                10 degrees    8                                                                15 degrees    8                                                                ______________________________________                                    

Table 3 shows the relation between the angle of elevation and the number of satellites using the angle of elevation as a parameter in the case where three satellites always visible from the observation point P are positioned on the orbit between OQ and OQ' of FIG. 10. It is desirable that these three satellites are distributed on a planar when viewed from the observation point P and should not be on a single line.

The method of distance measurement in the present embodiment is generally similar to that of the first embodiment, but in the present embodiment it is assumed that three satellites are on the stationary orbit, positioned latitudinally 8,600 km away from the equatorial plane and maximally spaced from one another, although the practical inter-satellite spacing is not so large as described above. Since the distance between two satellites is 31,500 km, as described above, the distance along which a signal transmitted by the satellite 1 at the position A is relayed by the satellites 2, 20 at the positions B, C and then reaches the observation point P is 99,000 km (=31,500×2+3,600) at the maximum. Thus, the time required for the signal propagation along this distance is about 0.33 seconds.

Also in this second embodiment, when the distance measurement signal and the time signal are transmitted between the eight satellites and between them and the observation point, the eight satellites are grouped into two groups including three satellites and one group including two satellites, and the combination of satellites in the respective groups is successively changed in the manner similar to that of the first embodiment described with reference to FIG. 18.

Construction of Satellites

The construction of the satellites for practising the method of position measurement described by way of the first and second embodiments will be described with reference to FIGS. 27 to 30. In a satellite shown in FIG. 27, the output of the timer device 211 controlled by a crystal oscillator 210 is supplied through telemetry device 212, transmitter 213, diplexer 214 and antenna 215 to the control station. The control station compares this signal with a signal having the primary reference level of the country and transmits to the satellite a command for finely adjusting the oscillation frequency of the crystal oscillator 210 and calibrating the timer device 211. This command is received through the antenna 215, a receiver 216 and a command receiver 217 which then supplies a command CM for correction to the crystal oscillator 210 and the timer device 211. The telemetry device 212 and the command receiver 217 are also used for usual satellite bus instruments in addition to for the calibration of time. The control station transmits a signal to the satellite for obtaining the distance therebetween and the rate of change in the distance. This signal is fed through a return route 218 and the receiver 216 to the transmitter 213. The control station uses this signal to determine the orbit of this satellite. A PRN code generator 220 receives a clock signal 219 from the timer device 211 and generates a series of PRN codes which are applied through a modulator 221 to a transmitter 222 and an antenna 223. At the same time, the output signal of the modulator 221 is transmitted through an amplifier 224, a diplexer 225 to an antenna 226 as a signal 227 to other satellites. In order to receive a signal from the preceding satellite and transmit the signal to the observation point and at the same time to the subsequent satellite, a signal 228 from the preceding satellite is received by the antenna 226, fed through the diplexer 225 and a receiver 229 to the transmitter 222 and transmitted by the antenna 223 to the observation point P. At the same time this signal is transmitted through a transmitter 230 and an antenna 231 to the subsequent satellite as a signal 232.

FIG. 28 shows the arrangement of a satellite which has a circuit for determining the inter-satellite distance in accordance with Equation (22). The signal 228 sent from another satellite is fed to a correlation device 240. To obtain a correlation between the signal 228 and the original signal, the output of the PRN code generator 220 is input to the correlation device 240. When a correlation between the signal 228 and a signal sent from the subsequent satellite is obtained, the signal 233 from the subsequent satellite is received by the antenna 231 and fed through the diplexer 234 and the receiver 235 to the correlation device 240.

The result calculated by the correlation device 240 is transmitted through the transmitter 222 and the antenna 223 to the observation point. Similar to the above-described correlation system, a correlation device 241 calculates a correlation between the signal 233 and the output of the PRN code generator 220 or between the signal 233 and the signal 228 and transmits the result through the telemetry device 212, the transmitter 213, the diplexer 214 and the antenna 215 to the control station.

FIG. 29 shows the construction of a satellite capable of transmitting a signal made by synthesizing the distance measurement signal and the time signal and having the signal format shown in FIG. 21. The modulator 221 generates a QPM signal such that the phase of the PRN code is in synchronism with the time when the PRN code is generated. The remaining elements of the satellite and the operation thereof are similar to those in FIG. 27 and further explanations are omitted here.

FIG. 30 shows a modification of the arrangement shown in FIG. 29. The signal 228 received by the antenna 226 from the preceding satellite is fed through the diplexer 225 to the receiver 229. The output of the receiver 229 is transmitted through the transmitter 230 and the antenna 231 to the subsequent satellite and at the same time fed to a demodulator/modulator 250. The demodulator/modulator 250 operates so as to reserve the distance measurement signal in the signal 228 and replace the time signal in the signal 228 with the time signal from a time code device 251. The output of the demodulator/modulator 250 is transmitted through the transmitter 222 and the antenna 223 to the observation point.

Although the present invention has been described in detail with a particular reference to some of the embodiments, it should be understood that those skilled in the art can achieve various changes and modifications without departing the spirit and scope of the present invention.

For example, the present invention should not be limited to the position determination of an observation point on the ground. The expression "observation point on the ground" should be considered throughout the description and the claims to include an observation point on the ground as well as an observation point other than on the ground. 

What is claimed is:
 1. A method of determining the position of an observation point on the earth using M satellites disposed on a predetermined orbit, comprising the steps of:(a) transmitting a reference signal at a predetermined time from a first of N satellites of the M satellites (N<M) to the observation point and to an adjacent subsequent N satellite, the orbit having a predetermined orbit inclination angle with respect to the equatorial plane such that the N satellites are simultaneously in the range of vision of the observation point; (b) causing, in sequential order, the adjacent subsequent N satellite and the remaining N satellites to transmit the reference signal to the observation point and to an adjacent subsequent satellite thereto; (c) measuring at the observation point the arrival times of the reference signals transmitted from the N satellites; (d) calculating the orbit position of the N satellites on the basis of the arrival times obtained in said step (c) and estimated values of the orbit position of the satellites within the predetermined orbit provided by a control station on the earth; and (e) determining at least three hyperboloids each having foci on adjacent two of the calculated orbit positions of the N satellites, whereby the position of the observation point is determined at an intersecting point of the hyperboloids.
 2. A method as set forth in claim 1, wherein said step (e) includes the step of calculating the mutual distance between two adjacent satellites of the N satellites.
 3. A method as set forth in claim 1, wherein the number M is four.
 4. A method of determining the position of an observation point on the earth using five or more satellites disposed on a predetermined orbit, comprising the steps of:(a) transmitting a reference signal at a predetermined time from a first of four satellites of the five or more satellites to the observation point and an adjacent subsequent satellite of the remaining three satellites, the predetermined orbit having the orbit inclination angle within the equatorial plane of substantially 6 degrees such that the four satellites are simultaneously in the range of vision of the observation point and the anomalies of the four satellites are separated from one another substantially at an angle of 120 degrees at the same point of time; (b) causing, in sequential order, the adjacent subsequent satellite and the remaining two satellites to transmit the reference signal to an adjacent subsequent satellite thereto; (c) causing, in sequential order, the respective adjacent subsequent satellite and the remaining two satellites to transmit the received reference signal to the observation point; (d) determining at the observation point the times of reception of the reference signals transmitted from the four satellites; (e) calculating the orbit positions of the four satellites using the reception times determined in said step (d) and estimated values of the orbit position of the four satellites within a predetermined orbit obtained from a control station on the earth; and (f) determining three hyperboloids each having foci on adjacent two of the calculated positions of the four satellites, whereby the position of the observation point is determined as an intersecting point of the hyperboloids.
 5. A method as set forth in claim 4, wherein said step (a) includes transmitting the reference signal from the first of the four satellites at a time calibrated by the control station.
 6. A method as set forth in claim 5, wherein said transmitting step of step (a) includes transmitting the reference signal from the first of the four satellites at a time calibrated by the control station at an integral-second time.
 7. A method as set forth in claim 6 further including the steps of calculating the mutual distance between a satellite and an adjacent subsequent satellite and transmitting the calculated results to the observation point.
 8. A method as set forth in claim 5, wherein said step (a) comprises:calibrating a clock means in the first of four satellites by a signal sent from the control station; in response to the calibrated clock means, transmitting from the first of four satellites a reference signal to the observation point; and transmitting from the first of four satellites the reference signal to the adjacent subsequent satellite.
 9. A method of determining the position of an observation point on the earth using five or more satellites disposed on a predetermined orbit, comprising the steps of:(a) transmitting a synthesized signal including a time signal designating a transmission time and a reference signal synchronized with the time signal, from a first of four adjacent satellites to the observation point and an adjacent subsequent satellite, the predetermined orbit having the orbit inclination angle with the equatorial plane of 6-10 degrees such that the four satellites are simultaneously in the range of vision of the observation point and the anomalies of the four satellites are separated from one another substantially at an angle of 120 degrees at the same point of time; (b) allowing, in sequential order, the adjacent subsequent satellite and the remaining two satellites to transmit a new synthesized signal including the reference signal and a time signal designating a time at the respective satellite, to the observation point and an adjacent subsequent satellite thereto; (c) determining at the observation point the times of reception of the signals transmitted from the four satellites; (d) calculating the orbit positions of the four satellites from the reception times determined in said step (c) and estimated values of the orbit position of the four satellites within the predetermined orbit obtained from the control station on the earth; and (e) determining three hyperboloids each having the foci on adjacent two of the calculated orbit positions of the four satellites, whereby the position of the observation point is determined as an intersecting point of the hyperboloids.
 10. A method as set forth in claim 9, wherein said steps (a) and (b) comprise:calibrating a clock means for producing a timing signal in the first of four satellites by a command signal sent from the control station; generating a reference signal for distance measurement; producing a synthesized signal including the timing signal and the reference signal; and transmitting from the first of four satellites the synthesized signal to the observation point and the adjacent subsequent satellite.
 11. A method as set forth in claim 10 wherein said calibrating step further includes the step of producing the command signal at the control station.
 12. A method as set forth in claim 11, wherein said producing step includes the step of producing the command signal on the basis of the time signal contained in the synthesized signal received by the observation point, the calculated positions of the orbits and the estimated values of the orbit positions of the four satellites and the standard time at the control station.
 13. A method of determining the position of an observation point on the earth using four satellites disposed on a predetermined orbit, comprising the steps of:(a) transmitting a synthesized signal including a time signal designating a transmission time and a reference signal synchronized with the time signal, from a first of adjacent three satellites to the observation point and to an adjacent subsequent satellite, the predetermined orbit having the orbit inclination angle with the equatorial plane of substantially 6 degrees such that the three adjacent satellites are simultaneously in the range of vision of the observation point and the anomalies of the three satellites are separated from one another substantially at an angle of 120 degrees at the same point of time; (b) allowing, in sequential order, the adjacent subsequent satellite and the remaining satellite to transmit a new synthesized signal including the synthesized signal and a time signal designating a time at the respective satellite, to the observation point and an adjacent subsequent satellite thereto; (c) repeating said steps (a) and (b) after the lapse of a period sufficient for detecting the orbit positions of the three satellites; (d) determining at the observation point the times of reception of the synthesizer signals transmitted from the three satellites in said steps (a) and (b); (e) calculating the positions of the three satellites when they perform the operations in said steps (a) and (b), using the times determined in said step (d) and estimated values of the orbit position of the three satellites within the predetermined orbit obtained from a control station on the earth; and (f) determining three hyperboloids each having the foci on adjacent two of the positions of the three satellites calculated in said step (e), whereby the position of the observation point is determined as an intersecting point of the hyperboloids.
 14. A method as set forth in claim 13, wherein said steps (a) and (b) comprise:calibrating a clock means for producing a timing signal in the first of adjacent three satellites by a command signal sent from the control station; generating a reference signal for distance measurement; producing a synthesized signal of the timing signal and the reference signal; transmitting the synthesized signal to the observation point and an adjacent subsequent satellite.
 15. A method as set forth in claim 14 wherein said calibrating step further includes a step of producing the command signal at the control station.
 16. A method as set forth in claim 15, wherein said producing step includes the step of producing the command signal on the basis of the time signal contained in the synthesized signal received by the observation point, the calculated positions of the orbit and the estimated values of the orbit positions of the respective three N satellites and the standard time at the control station.
 17. The method as recited in claim 1 wherein the predetermined orbit includes a geosynchronous orbit.
 18. The method as recited in claim 4 wherein the predetermined orbit includes a geosynchronous orbit.
 19. The method as recited in claim 9 wherein the predetermined orbit includes a geosynchronous orbit.
 20. The method as recited in claim 13 wherein the predetermined orbit includes a geosynchronous orbit. 